role of bluetooth le wireless sensors for smart buildings · sensors with just wireless...

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Role of Bluetooth LE Wireless Sensors for Smart Buildings

Dr. Darold WobschallPresident, Esensors Inc.

Niagara Technology and Security Forum

Bluetooth Sensor Networks 17/08 /2013

Topics

� Characteristics of smart sensors � Wireless sensor network options� Sensors for smart buildings, smart grid and IoT� Bluetooth sensor configurations� Application examples

Seminar intended for those with technical backgrounds

Bluetooth Sensor Networks 2

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Smart Sensor Characteristics

� Sensor Classes� Basic Sensors� Smart Sensors� Networked Sensors

Bluetooth Sensor Networks

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Basic Sensor Electronics Block Diagram


Va

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Partial List of Measured Parameters and Sensor Technologies

� Acceleration/vibration� Level & leak� Acoustic/ultrasound� Machine vision� Chemical/gas*� Motion/velocity/displacement� Electric/magnetic*� Position/presence/proximity� Flow� Pressure� Force/strain/torque� Temperature*� Humidity/moisture*

� Resistance� Capacitance� Inductance & magnetics� Optical & fiber optic� Voltage & piezoelectric� Ultrasonic� RF/microwave


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Technologies

Sensors (and sensor industry)are subdivided (fragmented) by:1. Parameter measured2. Technology3. Application area

* Used by Smart Grid

6Bluetooth Sensor Networks 6

Analog Signal Conditioners -- an example --

� Amplifier for piezoelectric motion sensor with demodulated signal is shown below:

� Amplifier is very low power so digital section can be in sleep mode

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Sensors with Digital I/O

� More sensors with digital outputs (but with internal analog signal conditioners and a/d) becoming available.

� Output format is usually I2C or SPI and thus requires further reformatting – not a smart sensor in itself

� Example: temperature sensor (LM74)(SPI 12-Bit plus sign, +/- 0.0625 ºC)

Smart Sensor Block Diagram


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Smart (Digital) Sensor Features

� Analog/Digital ConverterTypically 10-14 bits, usually internal

� Microcontroller (embedded)PIC or similar 8-bit (or 16-bit) micro with appropriate features

� Sensor Identification (serial # etc)� Calibration information

Compensation for sensor variations; conversion to engineering units

� Data logging and real-time clock (optional)


Connection of Non-networked Smart Sensorsto Computers

� Serial Data Lines: USB (best for PCs)or RS232 (best for Instruments)

� One line and port per sensor (a problem with large systems)

� Data is digital but format is often not standardized

� Not a common configuration – most smart sensors are now networked


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Networked Sensor Block Diagram(local network or bus)


Parameter in


Multi-level Data Protocols

� Data formats: How commands and transducer data are encoded (e.g. units, data type). Must be standard format for machine readability (M-to-M).

� Communication formats: How digital data is transmitted over network (e. g. IEEE 802.15.2g WiFi). Associated with physical (hardware) layer.

� Multi-level often has encapsulated data of form:

Header(Subheader{data}subfooter)footer

� On Internet TCP/IP data often uses XML format

� Narrow application sensor network protocols sometimes combine data and communication formats

� Numerous sensors formats and standard in use (unfortunately)

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Busses and Networks Overview-- Wired and Wireless

� Analog (Industrial)� 0-5v

� 4-20 ma loop

� Wired (digital)� Ethernet

� RS232/RS485

� USB

� PLC

� Wireless� Next slides


Wireless Data Transmission Classes

� Licensed� – high power, long distance and high cost

� Unlicensed ISM Band (Industrial, Scientific and Medical)

� -- low power, short range, low cost

� Normally used for wireless sensor networks

� Cellular� 4G

� Satellite phone


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Non-networked Wireless Sensors(not covered here)

� Smart sensors are usually networked

� Observation: low-cost sensors are not networked and non-networked sensors are not low cost (at least up to now)

� Some simple (and cheap) non-networked wireless consumer products and toys are shown below


ISM Frequency Bandsfor sensor networks

Main Bands (USA)� 433 Mhz

� 915 Mhz

� 2.4 Ghz <– most popular

Sometimes used� Lower: 24, 40, 315 Mhz

� Higher: 5.8, 24 GHz


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Wireless Sensor Popular Options in ISM band

� WiFi � IEEE 802.11b,g

� Bluetooth � Older is 2.0, newer is 4.0 low energy -- LE has better range,

connects easily but low bandwidth –good for sensors

� Mesh using IEEE 802.15.4 technology

� Mesh networks provides data hopping

� Includes Zigbee, 6LoWPAN, ISA100 and Wireless HART

� SubGHz � Lowest cost and power

� Often transmit-only17

Wireless Comparisons

� xxxBluetooth Sensor Networks 18

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Wireless Star Networkfor Buildings or Local Area

� Data transferred from each sensor to gateway directly

� Example: WiFi

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Bluetooth Sensor Networks20

Wireless Mesh Networkfor Buildings or Local Areas

� Data hops from node to node

� Optimum data transfer varies with technology

� Example: Zigbee

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Low Power Wireless Networks

� Goal: years of battery life (< 100 µa @ 3v)

� Analog/sensor section and microcontroller circuits must be low power

� Sleep mode used extensively to reduce average current draw

� Transmitter/receiver activated infrequently and briefly

� WiFi, Bluetooth and Zigbee/mesh have low power modes. We like Bluetooth LE

� Energy harvesting may be employed (no battery)


Transmit-only Sensors

� Sensors with just wireless transmitters are simpler

� Normally event driven (e.g. motion)

� May have a periodic beacon or heartbeat

� Typically low-power battery or energy harvest supply

� Lowest cost wireless sensor

� Often reporting to another, two-way wireless sensor


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Conventional Bluetooth Sensor Network

� Bluetooth talks to smart phones and tables

� Smart phones display data as Apps

� Sensors usually provide personal information� Examples: heart rate, air quality

� Internet access, if needed, is via cellular link� But no access if smart phone is not in vicinity


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Fixed Location Bluetooth Sensors

� For smart buildings monitoring and controls

� Low energy (LE) or 4.0 has better distance and lower power

� Gateway to Internet needed

� Expect mix of battery and line powered sensors

� For longer range, wireless relays or repeaters needed� Zigbee or 6LoWPAN convenient


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Bluetooth LE Gateway-- a proposed solution

� Bluetooth sensors for smart building (or smart grid) require Internet access via a gateway – few available

� Gateway functions similar to WiFi router

� Gateway also has sensor conditioning and translation software (APIs)

� Application example� Point of load power meter which is accessed by Brower to monitor

energy usage

� Esensors wishes to find funding to develop this gateway

� Link: gateway page


Specialized Dashboards– examples of proprietary displays --

� Iconics Energyanalytix� Google Powermeter� Esensors PM31 monitor


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Main Areas of Applicationfor Bluetooth sensors

� Internet of Things (IoT)� Smart Grid� Smart Buildings� Medical/personal


Smart sensors for IoT

� Internet of Things (IoT) concept is interconnection of all digital devices or objects via the “cloud”

� Sensors are a major part of the IoT – could be billions

� Related to Machine-to-Machine (MtoM) compatibility

� Sensor data format is fixed, unambiguous and not require human intervention

� A series of standards are required, including IEEE 21451-1-4


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Smart Grid Concepts

� The electrical grid upgraded by two-way digital communication for greatly enhanced monitoring and control

� Saves energy, reduces costs and increases reliability� Involves national grid as well as local micro-grid ---

power generation, transmission, distribution and users� Real-time (smart) metering of consumer loads is a key feature� Phasor network another key feature (Phasor Measurement Unit, PMU)

� Uses integrated communication (requires standards)� Includes advanced features (e.g., energy storage, solar power)� Requires multiple power meters and other sensors, specially at loads

All networked



Smart Building Sensing Goals

� Integration of HVAC, fire, security and other building services

� Reduce energy use

� Automation of operations

� Interaction with outside service providers (e.g. utilities)

� Three main wired standards:� BACnet , Lonworks and Modbus

� Poplar wireless standards:� WiFi , Zigbee (but Bluetooth, 4G, proprietary gaining acceptance)

� Two smart building organizations� ASRAE (American Society of Heating, Refrigerating and Air-Conditioning Engineers)

� Remote Site & Equipment Management

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Relationship of IoT Sensors toSmart Grid and Smart Buildings

� IoT aims to cover all sensors on the Internet� Many electrical devices (e.g. lighting, motors) are

part of both smart grid and smart building areas� Many smart sensors are used for both� Sensor networks are the same or similar for both


IP Based Networks

� Internet Protocol (IP) based networks are used for data communication involving the smart grid and most smart buildings

� Acts as bridge between application and underlying sensor/control networks

� Used by both private (dedicated) and public networks

� Used also by local wireless networks

� Need to interface (via translators) with popular and legacy networks such as Modbus, BACnet, DALI and Lonworks


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Internet Protocols

� Smart Grid uses Internet Protocol (IP) for all data communications

� Specific protocols are:� HTTP

The most basic for data transfer� XML

Widely used because of self-identifying format� SNMP

Message protocol popular within data centers� SOAP

XML-based protocol for cross platform communication


Smart Building Applicationsfor Smart Sensors

� HVAC� Environmental and comfort� Lighting control� Energy monitoring


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HVAC Sensors(Heating, Ventilation and Air Conditioning)

� Temperature� Humidity� Air Flow� Air quality (gases: CO2, CO, VOC)� Also Actuators (control of heating,

ventilation, AC)

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Smart building communication choiceswith connection to Internet

� Ethernet� Lowest cost to Internet

� Installed base but often not at sensor site

� Other wired*� USB, RS232, RS485, Lonworks, DALI

� WiFi� Mobile and convenient (if router * already present)

� Local wireless (LAN)*� Mesh: Zigbee, 6LoWPAN, Wireless HART, ISA100

� Bluetooth� Pending gateway development

� Powerline*� Attractive concept but both narrowband and wideband not fully proven

� Cell phone� SMS, G4 modems available but costly (and requires higher power)

� Highly mobile and convenient

* Requires gateway to reach Internet

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37Bluetooth Sensor Networks

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Energy Conservation

� Smart meters (at Microgrid level) provide information needed to analyze energy usage and thus allow energy minimization algorithms to be implemented

� Real time data, best at individual loads

� Control programs by utilities or private companies

New ZigBee Smart Energy Version 1.1

Now Available

Smart Sensor Locations in an Auditorium-- Bluetooth examples --


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� Sensors are distributed within room

� Gateway within range of sensors

� Gateway connects to Internet

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Smart Sensor Locations in a Building-- example --

� Sensors are distributed within building

� Gateway connects to Internet

� Wireless repeater (relay) extends distance

� Power metering and HVAC/lighting controls included


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Gateway

Personal Monitoring with a Building- assisted living home example -

� Sensors located in individual rooms and common areas

� Multiple types � Motion� Location� Door open/close� Alarm

� Can handle hundreds/thousands of sensors – local and Internet alerts


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Standards and Interoperability

� TCP/IP is only the communication protocol used

(at least on the Internet)

� Data carried as payload will be formatted by specific standards

� Over 100 Standards referenced in NIST Guidelines for smart grid – also many for IoT

� We support the IEEE/IEC 21451 set of standard for sensor data formatting


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IEEE 1451 – the Universal Transducer Language-- new name IEEE/ISO 21451-x series

� Problem: too many network protocols in common use� Narrow solutions and borrowed protocols have not

worked� Sensor engineers in the fragmented sensor industry

need a simple method of implementation

� How can it be done?� We need something like USB, except for sensors� Solution: the IEEE 1451 Smart Transducer Protocol

open standard is the best universal solution� Supported by NIST, IEEE and many Federal agencies

� More information available� Link: http://www.eesensors.com/ieee-1451/

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Summary of Topics Covered

� Characteristics of smart sensors � Wireless sensor network options� Sensors for smart buildings and smart grid� Bluetooth sensor configurations� Application examples

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Contact: [email protected]


End

� Backup Slides Follow

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www.eesensors.com

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Sensor/Transducer Networks

� A network connects more than one addressed sensor (or actuator) to a digital wired or wireless network

� Both network and sensor digital data protocols are needed

� Standard data networks can be used but are far from optimum

� Numerous (>100) incompatible sensor networks are currently in use – each speaking a different language

45The Tower of Babel

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Status of Various Parts of IEEE 1451Parts not developed in order

� 1451.0 – Basic data/TEDS format Done (2007)� 1451.1 – NCAP/Computer Interface Done (1999) note1

� 1451.2 – Serial Revised (2013) note 2

� [1451.3 – Wired Multi-drop Done (2002) note3

� 1451.4 – TEDS Only Done (2005)

� 1451.5 – Wireless (WiFi, Zigbee, etc) Done (2007)

� 1451.7 – RFID Done (2010)

Note 1: Being revised

Note 2 : Original Dot 2 in 1997 –being reballoted as ISO standard

Note 3: Obsolete (hardware unavailable)

Dot 2 Description

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Dot 2 Block Diagram

� First

Dot 2 Description

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IEEE 1451 Command/Response

� Command format:� Header (6 bytes), Command (variable)

� Response Format:� Header (3 bytes), Data (variable)

� Command Examples (from NCAP to TIM)� TIM Discovery (to see which TIMs are available)

� Channel Discovery (to see which Transducers are available)

� Read TEDS (individually) – mostly binary

� Data Return Examples (from TIM to NCAP)� Data from Chan. 1 (# bytes and data type, e.g. 16-bit integer, set by TEDS)

� Data from Chan 2

� Commands and responses same for all types of sensors and physical layers on Network (Internet) side -- suitable for M2M & web networks

� About 37 commands, many specialized (e.g. trigger, sleep, configure)48

Dot 2 Description

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IEEE 1451 Command/Response

� Command format:� Header (6 bytes), Command (variable)

� Response Format:� Header (3 bytes), Data (variable)

� Command Examples (from NCAP to TIM)� TIM Discovery (to see which TIMs are available)

� Channel Discovery (to see which Transducers are available)

� Read TEDS (individually) – mostly binary

� Data Return Examples (from TIM to NCAP)� Data from Chan. 1 (# bytes and data type, e.g. 16-bit integer, set by TEDS)

� Data from Chan 2

� Commands and responses same for all types of sensors and physical layers on Network (Internet) side -- suitable for M2M & web networks

� About 37 commands, many specialized (e.g. trigger, sleep, configure)49

Dot 2 Description


Network side (NCAP) options(wired)

� Internet/Ethernet

� PC Readout

� Industrial

network

All use Dot 0 protocol

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Demonstration NCAP and TIMFor Dot 2, Dot 4 and Dot 5

System Block Diagram

Dot 2 Description

Manual: http://www.eesensors.com/media/wysiwyg/pdf/1451_manual.pdf

Open AccessDownloadsAvailable


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Wireless Sensors (Uses RF transceivers for short-range in unlicensed band)

� Significant power available� Line-powered or laptop sized battery

� E.g. WiFi (IEEE 802.11b, 2.4 GHz)

� Variation of TCP/IP protocol, mostly non-standard

� Medium low power � Re-chargeable batteries or shorter life applications

� Cellular (GSM, 4G) – especially outside buildings

� Very low power (long life operation -years)

� Batteries or energy harvesting

� Low bandwidth, sleep mode

� Sensor signal conditions must be low power52

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Prospects for

Smart Appliances

� Examples: smart refrigerator, smart dryer

� Two-way communication via Internet

� Logical extension of smart grid/buildings

� Technically possible for years but …� Hardware costs high� Installation may be complex (best plug & play)� Standards lacking

� Will disconnect feature be implemented?

� Privacy concerns high

� Benefits unclear

� Futuristic discussion

mostly


Power Line Communication (PLC)

� Narrow-band (NB) Devices� Low frequency operation (e.g. 10 to 500 kHz)� Low data rate but good match for most sensors� Typically aimed at home (120v) – but also some high voltage applications� “X10” is the oldest protocol (pulses at zero-crossing)� Noise/interference and phase-to-phase loss are significant problems� Various new protocols and ICs have been developed – next slide� Usually more costly than wireless

� Broad-band devices� HomePlug HomePNA) AV (IEEE 1901) becoming used (carries Internet)� Frequency range: 4.5 to 20.7 MHz� Speed of 500 Mbits/sec (up to 100 MHz)� Interference a continuing problem (notching required by FCC)

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DALI -- lighting

� Digital Addressable Lighting Interface (DALI) was developed for remote lighting control (e.g. dimmers)

� Rugged bus (64 devices, data & power on 2-wire bus)

� Asynchronous, half-duplex, serial protocol at 1200 Baud

� Requires controller (master) or gateway

� More popular in Europe

� Sensor bus based on DALI available


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DALI – for sensors

� DALI extended to general purpose sensor bus (sensor is slave)

� Advantage of power and data on same 2-wire bus

� Higher data rate (9600 baud)

� Allows mix of standard and sensor DALI format on bus

� Allows TEDS and standard formats for sensors

� Actuators also

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Time Sync via Ethernet (Internet)

� Time in µs available from NIST via Internet in several formats (widely used). --Accuracy typically 0.1 sec

� For local synchronization a master clock on one Ethernet node is used which is synchronized to other nodes via IEEE 1588 Precision Clock Synchronization Protocol� Relative precision typically 0.05 µs between local nodes� Wireless precision to 1-10 µs (over IEEE 802.15.4)

� NTP format -- 64-bit timestamp containing the time in UTC sec since EPOCH (Jan 1, 1900), resolved to 0.2 µs� Upper 32 bits: number of seconds since EPOCH� Lower 32 bits: binary fraction of second

57Networked Smart Grid Sensors


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Air Quality Sensorsfor smart buildings

� Main gases: � Carbon Dioxide (CO2)

CO2 buildup in rooms when people present – signal for increased ventilation

� Volatile Organic Compounds (VOC) and Carbon monoxide (CO)Potentially harmful gases (possibly toxic also)

� Signal Conditioners� Requires both analog and digital� Multiple sensor technologies complicates design

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Energy Conservation Sensors

� Temperature� Illumination� Occupancy sensors� Wireless room controls (e.g. lighting)� Remote access (Smart grid, Internet)


Building Control Networks(HVAC, lighting)

� Modbus (RS232/serial originally)

� BACnet - building automation and controls network (originally RS485)

� LonWorks (2-wire proprietary)

� All have TCP/IP (Ethernet) extensions, now commonly used

� Wireless versions (WiFi, Zigbee,6LoWPAN)

� Some command examples ( BACnet)� Read Property� Write Property� Device Communication Control� ReinitializeDevice� Time Synchronization

60Networked Smart Grid Sensors

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Mod-bus

� Monitoring and control for HVAC and industrial applications

� Simple format and limited functions, developed for PLCs

� Originally RS232 and RS485 (serial)

� Industrial Ethernet (TCP/IP) version popular

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SCADA and PMU Standards

� Supervisory Control and Data Acquisition is current control system which has these parts:� Human-Machine Interface(HMI)

� Remote Terminal Units(RTUs) – converts sensor signals to digital data (alternative: Programmable Logic Controller)

� Communicationinfrastructure connects to the supervisory system

� Uses Modbus and other sensor

networks (also TCP/IP extensions)

� Phasor Measurement Unit protocol uses

cycle by cycle phase measurements

plus SCADA and other information

via dedicated network

Networked Smart Grid Sensors

Human-Machine Interface(from Wikipedia) 62Bluetooth Sensor Networks

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Automatic meter reading (AMR)

� Improved is Advanced Metering Infrastructure (AMI) or Smart meters (2-way)

� Used for revenue

� Wireless based � Many proprietary� Moderate range, drive-by reading� Mesh (Zigbee) and WiFi sometimes � Usually not Internet connected

� About 50M AMR/AMI installed (USA)

� Suggested standard: ANSI C12.18


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Energy Conservation -- 2

� Energy usage monitoring websites

� Power use vs time ($ calculated)

� Google Powermeter and MS Hohm discontinued

� Others available – eMonitor,

Tendril, Wattvision,

PowerCost Monitor

� 5% to 30% (12% avr) savings

reported in usage studies

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Demand/Response

� Electrical load reduction (load shedding) in response to high demand on the grid (utilities issue alert)

� Purpose is to shave peak demand and reduce reserve power requirements (and build fewer power plants)

� Large rate increases during peak demand discourage consumption

� Implemented by utilities or third parties through contract (shed load when requested in return for lower rates)

� Requires smart meter at customer site

role of bluetooth le wireless sensors for smart buildings · sensors with just wireless...

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